355 lines
11 KiB
Plaintext
355 lines
11 KiB
Plaintext
dnl AC_NEED_BYTEORDER_H ( HEADER-TO-GENERATE )
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dnl Copyright 2001-2002 by Dan Fandrich <dan@coneharvesters.com>
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dnl This file may be copied and used freely without restrictions. No warranty
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dnl is expressed or implied.
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dnl
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dnl Create a header file that guarantees that byte swapping macros of the
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dnl ntohl variety as well as the extended types included in OpenBSD and
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dnl NetBSD such as le32toh are defined. If possible, the standard ntohl
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dnl are overloaded as they are optimized for the given platform, but when
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dnl this is not possible (e.g. on a big-endian machine) they are defined
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dnl in this file.
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dnl Look for a symbol in a header file
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dnl AC_HAVE_SYMBOL ( IDENTIFIER, HEADER-FILE, ACTION-IF-FOUND, ACTION-IF-NOT-FOUND )
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AC_DEFUN([AC_HAVE_SYMBOL],
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[
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AC_MSG_CHECKING(for $1 in $2)
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AC_EGREP_CPP([symbol is present|\<$1\>],[
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#include <$2>
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#ifdef $1
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symbol is present
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#endif
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],
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[AC_MSG_RESULT(yes)
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$3
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],
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[AC_MSG_RESULT(no)
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$4
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])])
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dnl Create a header file that defines extended byte swapping macros
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AC_DEFUN([AC_NEED_BYTEORDER_H],
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[
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changequote(, )dnl
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ac_dir=`echo $1|sed 's%/[^/][^/]*$%%'`
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changequote([, ])dnl
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if test "$ac_dir" != "$1" && test "$ac_dir" != .; then
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# The file is in a subdirectory.
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test ! -d "$ac_dir" && mkdir "$ac_dir"
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fi
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# We're only interested in the target CPU, but it's not always set
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effective_target="$target"
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if test "x$effective_target" = xNONE -o "x$effective_target" = x ; then
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effective_target="$host"
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fi
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AC_SUBST(effective_target)
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cat > "$1" << EOF
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/* This file is generated automatically by configure */
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/* It is valid only for the system type ${effective_target} */
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#ifndef __BYTEORDER_H
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#define __BYTEORDER_H
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EOF
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dnl First, do an endian check
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AC_C_BIGENDIAN
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dnl Look for NetBSD-style extended byte swapping macros
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AC_HAVE_SYMBOL(le32toh,machine/endian.h,
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[HAVE_LE32TOH=1
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cat >> "$1" << EOF
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/* extended byte swapping macros are already available */
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#include <machine/endian.h>
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EOF],
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[
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dnl Look for standard byte swapping macros
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AC_HAVE_SYMBOL(ntohl,arpa/inet.h,
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[cat >> "$1" << EOF
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/* ntohl and relatives live here */
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#include <arpa/inet.h>
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EOF],
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[AC_HAVE_SYMBOL(ntohl,netinet/in.h,
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[cat >> "$1" << EOF
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/* ntohl and relatives live here */
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#include <netinet/in.h>
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EOF],true)])
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])
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dnl Look for generic byte swapping macros
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dnl OpenBSD
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AC_HAVE_SYMBOL(swap32,machine/endian.h,
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[cat >> "$1" << EOF
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/* swap32 and swap16 are defined in machine/endian.h */
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EOF],
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[
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dnl Linux GLIBC
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AC_HAVE_SYMBOL(bswap_32,byteswap.h,
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[cat >> "$1" << EOF
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/* Define generic byte swapping functions */
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#include <byteswap.h>
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#define swap16(x) bswap_16(x)
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#define swap32(x) bswap_32(x)
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#define swap64(x) bswap_64(x)
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EOF],
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[
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dnl NetBSD
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AC_HAVE_SYMBOL(bswap32,machine/endian.h,
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dnl We're already including machine/endian.h if this test succeeds
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[cat >> "$1" << EOF
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/* Define generic byte swapping functions */
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EOF
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if test "$HAVE_LE32TOH" != "1"; then
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echo '#include <machine/endian.h>'>> "$1"
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fi
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cat >> "$1" << EOF
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#define swap16(x) bswap16(x)
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#define swap32(x) bswap32(x)
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#define swap64(x) bswap64(x)
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EOF],
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[
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dnl FreeBSD
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AC_HAVE_SYMBOL(__byte_swap_long,sys/types.h,
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[cat >> "$1" << EOF
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/* Define generic byte swapping functions */
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#include <sys/types.h>
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#define swap16(x) __byte_swap_word(x)
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#define swap32(x) __byte_swap_long(x)
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/* No optimized 64 bit byte swapping macro is available */
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#define swap64(x) ((uint64_t)(((uint64_t)(x) << 56) & 0xff00000000000000ULL | \\
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((uint64_t)(x) << 40) & 0x00ff000000000000ULL | \\
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((uint64_t)(x) << 24) & 0x0000ff0000000000ULL | \\
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((uint64_t)(x) << 8) & 0x000000ff00000000ULL | \\
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((x) >> 8) & 0x00000000ff000000ULL | \\
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((x) >> 24) & 0x0000000000ff0000ULL | \\
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((x) >> 40) & 0x000000000000ff00ULL | \\
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((x) >> 56) & 0x00000000000000ffULL))
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EOF],
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[
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dnl OS X
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AC_HAVE_SYMBOL(NXSwapLong,machine/byte_order.h,
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[cat >> "$1" << EOF
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/* Define generic byte swapping functions */
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#include <machine/byte_order.h>
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#define swap16(x) NXSwapShort(x)
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#define swap32(x) NXSwapLong(x)
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#define swap64(x) NXSwapLongLong(x)
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EOF],
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[
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if test $ac_cv_c_bigendian = yes; then
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cat >> "$1" << EOF
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/* No other byte swapping functions are available on this big-endian system */
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#define swap16(x) ((uint16_t)(((x) << 8) | ((uint16_t)(x) >> 8)))
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#define swap32(x) ((uint32_t)(((uint32_t)(x) << 24) & 0xff000000UL | \\
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((uint32_t)(x) << 8) & 0x00ff0000UL | \\
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((x) >> 8) & 0x0000ff00UL | \\
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((x) >> 24) & 0x000000ffUL))
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#define swap64(x) ((uint64_t)(((uint64_t)(x) << 56) & 0xff00000000000000ULL | \\
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((uint64_t)(x) << 40) & 0x00ff000000000000ULL | \\
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((uint64_t)(x) << 24) & 0x0000ff0000000000ULL | \\
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((uint64_t)(x) << 8) & 0x000000ff00000000ULL | \\
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((x) >> 8) & 0x00000000ff000000ULL | \\
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((x) >> 24) & 0x0000000000ff0000ULL | \\
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((x) >> 40) & 0x000000000000ff00ULL | \\
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((x) >> 56) & 0x00000000000000ffULL))
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EOF
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else
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cat >> "$1" << EOF
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/* Use these as generic byteswapping macros on this little endian system */
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#define swap16(x) ntohs(x)
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#define swap32(x) ntohl(x)
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/* No optimized 64 bit byte swapping macro is available */
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#define swap64(x) ((uint64_t)(((uint64_t)(x) << 56) & 0xff00000000000000ULL | \\
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((uint64_t)(x) << 40) & 0x00ff000000000000ULL | \\
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((uint64_t)(x) << 24) & 0x0000ff0000000000ULL | \\
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((uint64_t)(x) << 8) & 0x000000ff00000000ULL | \\
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((x) >> 8) & 0x00000000ff000000ULL | \\
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((x) >> 24) & 0x0000000000ff0000ULL | \\
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((x) >> 40) & 0x000000000000ff00ULL | \\
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((x) >> 56) & 0x00000000000000ffULL))
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EOF
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fi
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])
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])
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])
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])
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])
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[
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if test "$HAVE_LE32TOH" != "1"; then
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cat >> "$1" << EOF
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/* The byte swapping macros have the form: */
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/* EENN[a]toh or htoEENN[a] where EE is be (big endian) or */
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/* le (little-endian), NN is 16 or 32 (number of bits) and a, */
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/* if present, indicates that the endian side is a pointer to an */
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/* array of uint8_t bytes instead of an integer of the specified length. */
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/* h refers to the host's ordering method. */
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/* So, to convert a 32-bit integer stored in a buffer in little-endian */
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/* format into a uint32_t usable on this machine, you could use: */
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/* uint32_t value = le32atoh(&buf[3]); */
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/* To put that value back into the buffer, you could use: */
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/* htole32a(&buf[3], value); */
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/* Define aliases for the standard byte swapping macros */
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/* Arguments to these macros must be properly aligned on natural word */
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/* boundaries in order to work properly on all architectures */
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#define htobe16(x) htons(x)
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#define htobe32(x) htonl(x)
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#define be16toh(x) ntohs(x)
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#define be32toh(x) ntohl(x)
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#define HTOBE16(x) (x) = htobe16(x)
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#define HTOBE32(x) (x) = htobe32(x)
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#define BE32TOH(x) (x) = be32toh(x)
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#define BE16TOH(x) (x) = be16toh(x)
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EOF
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if test $ac_cv_c_bigendian = yes; then
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cat >> "$1" << EOF
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/* Define our own extended byte swapping macros for big-endian machines */
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#define htole16(x) swap16(x)
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#define htole32(x) swap32(x)
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#define le16toh(x) swap16(x)
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#define le32toh(x) swap32(x)
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#define htobe64(x) (x)
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#define be64toh(x) (x)
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#define HTOLE16(x) (x) = htole16(x)
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#define HTOLE32(x) (x) = htole32(x)
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#define LE16TOH(x) (x) = le16toh(x)
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#define LE32TOH(x) (x) = le32toh(x)
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#define HTOBE64(x) (void) (x)
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#define BE64TOH(x) (void) (x)
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EOF
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else
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cat >> "$1" << EOF
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/* On little endian machines, these macros are null */
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#define htole16(x) (x)
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#define htole32(x) (x)
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#define htole64(x) (x)
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#define le16toh(x) (x)
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#define le32toh(x) (x)
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#define le64toh(x) (x)
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#define HTOLE16(x) (void) (x)
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#define HTOLE32(x) (void) (x)
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#define HTOLE64(x) (void) (x)
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#define LE16TOH(x) (void) (x)
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#define LE32TOH(x) (void) (x)
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#define LE64TOH(x) (void) (x)
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/* These don't have standard aliases */
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#define htobe64(x) swap64(x)
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#define be64toh(x) swap64(x)
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#define HTOBE64(x) (x) = htobe64(x)
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#define BE64TOH(x) (x) = be64toh(x)
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EOF
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fi
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fi
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cat >> "$1" << EOF
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/* Define the C99 standard length-specific integer types */
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#include <_stdint.h>
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EOF
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case "${effective_target}" in
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i[3456]86-*)
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cat >> "$1" << EOF
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/* Here are some macros to create integers from a byte array */
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/* These are used to get and put integers from/into a uint8_t array */
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/* with a specific endianness. This is the most portable way to generate */
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/* and read messages to a network or serial device. Each member of a */
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/* packet structure must be handled separately. */
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/* The i386 and compatibles can handle unaligned memory access, */
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/* so use the optimized macros above to do this job */
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#define be16atoh(x) be16toh(*(uint16_t*)(x))
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#define be32atoh(x) be32toh(*(uint32_t*)(x))
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#define be64atoh(x) be64toh(*(uint64_t*)(x))
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#define le16atoh(x) le16toh(*(uint16_t*)(x))
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#define le32atoh(x) le32toh(*(uint32_t*)(x))
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#define le64atoh(x) le64toh(*(uint64_t*)(x))
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#define htobe16a(a,x) *(uint16_t*)(a) = htobe16(x)
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#define htobe32a(a,x) *(uint32_t*)(a) = htobe32(x)
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#define htobe64a(a,x) *(uint64_t*)(a) = htobe64(x)
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#define htole16a(a,x) *(uint16_t*)(a) = htole16(x)
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#define htole32a(a,x) *(uint32_t*)(a) = htole32(x)
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#define htole64a(a,x) *(uint64_t*)(a) = htole64(x)
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EOF
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;;
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*)
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cat >> "$1" << EOF
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/* Here are some macros to create integers from a byte array */
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/* These are used to get and put integers from/into a uint8_t array */
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/* with a specific endianness. This is the most portable way to generate */
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/* and read messages to a network or serial device. Each member of a */
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/* packet structure must be handled separately. */
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/* Non-optimized but portable macros */
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#define be16atoh(x) ((uint16_t)(((x)[0]<<8)|(x)[1]))
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#define be32atoh(x) ((uint32_t)(((x)[0]<<24)|((x)[1]<<16)|((x)[2]<<8)|(x)[3]))
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#define be64atoh(x) ((uint64_t)(((x)[0]<<56)|((x)[1]<<48)|((x)[2]<<40)| \\
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((x)[3]<<32)|((x)[4]<<24)|((x)[5]<<16)|((x)[6]<<8)|(x)[7]))
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#define le16atoh(x) ((uint16_t)(((x)[1]<<8)|(x)[0]))
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#define le32atoh(x) ((uint32_t)(((x)[3]<<24)|((x)[2]<<16)|((x)[1]<<8)|(x)[0]))
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#define le64atoh(x) ((uint64_t)(((x)[7]<<56)|((x)[6]<<48)|((x)[5]<<40)| \\
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((x)[4]<<32)|((x)[3]<<24)|((x)[2]<<16)|((x)[1]<<8)|(x)[0]))
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#define htobe16a(a,x) (a)[0]=(uint8_t)((x)>>8), (a)[1]=(uint8_t)(x)
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#define htobe32a(a,x) (a)[0]=(uint8_t)((x)>>24), (a)[1]=(uint8_t)((x)>>16), \\
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(a)[2]=(uint8_t)((x)>>8), (a)[3]=(uint8_t)(x)
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#define htobe64a(a,x) (a)[0]=(uint8_t)((x)>>56), (a)[1]=(uint8_t)((x)>>48), \\
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(a)[2]=(uint8_t)((x)>>40), (a)[3]=(uint8_t)((x)>>32), \\
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(a)[4]=(uint8_t)((x)>>24), (a)[5]=(uint8_t)((x)>>16), \\
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(a)[6]=(uint8_t)((x)>>8), (a)[7]=(uint8_t)(x)
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#define htole16a(a,x) (a)[1]=(uint8_t)((x)>>8), (a)[0]=(uint8_t)(x)
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#define htole32a(a,x) (a)[3]=(uint8_t)((x)>>24), (a)[2]=(uint8_t)((x)>>16), \\
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(a)[1]=(uint8_t)((x)>>8), (a)[0]=(uint8_t)(x)
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#define htole64a(a,x) (a)[7]=(uint8_t)((x)>>56), (a)[6]=(uint8_t)((x)>>48), \\
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(a)[5]=(uint8_t)((x)>>40), (a)[4]=(uint8_t)((x)>>32), \\
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(a)[3]=(uint8_t)((x)>>24), (a)[2]=(uint8_t)((x)>>16), \\
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(a)[1]=(uint8_t)((x)>>8), (a)[0]=(uint8_t)(x)
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EOF
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;;
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esac
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]
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cat >> "$1" << EOF
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#endif /*__BYTEORDER_H*/
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EOF])
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